Edge: THE NEUROLOGY OF SELF-AWARENESS by V.S. Ramachandran: As noted earlier there is one aspect of self that seems stranger than all the others — the fact that it is aware of itself. I would like to suggest that groups of neurons called mirror neurons are critically involved in this ability.... [W]hen the monkey reached for a peanut a certain neuron in its pre motor cortex (in the frontal lobes) would fire. Another neuron would fire when the monkey pushed a button, a third neuron when he pulled a lever. The existence of such Command neurons that control voluntary movements has been known for decades. Amazingly, a subset of these neurons had an additional peculiar property. The neuron fired not only (say) when the monkey reached for a peanut but also when it watched another monkey reach for a peanut!

These were dubbed "mirror neurons" or "monkey-see-monkey-do" neurons. This was an extraordinary observation because it implies that the neuron (or more accurately, the network which it is part of) was not only generating a highly specific command ("reach for the nut") but was capable of adopting another monkey's point of view. It was doing a sort of internal virtual reality simulation of the other monkeys action in order to figure out what he was "up to". It was, in short, a "mind-reading" neuron.

Neurons in the anterior cingulate will respond to the patient being poked with a needle; they are often referred to as sensory pain neurons. Remarkably, researchers at the University of Toronto have found that some of them will fire equally strongly when the patient watches someone else is poked. I call these "empathy neurons" or "Dalai Lama neurons" for they are, dissolving the barrier between self and others. Notice that in saying this one isn't being metaphorical; the neuron in question simply doesn't know the difference between it and others.

Primates (including humans) are highly social creatures and knowing what someone is "up to" — creating an internal simulation of his/her mind — is crucial for survival, earning us the title "the Machiavellian primate". In an essay for Edge (2001) entitled "Mirror Neurons and the Great Leap Forward" I suggested that in addition to providing a neural substrate for figuring out another persons intentions (as noted by Rizzolati's group) the emergence and subsequent sophistication of mirror neurons in hominids may have played a crucial role in many quintessentially human abilities such as empathy, learning through imitation (rather than trial and error), and the rapid transmission of what we call "culture". And the "great leap forward" — the rapid Lamarckian transmission of "accidental" one-of-a kind inventions.

I turn now to the main concern of this essay — the nature of self. When you think of your own self, what comes into mind? You have sense of "introspecting" on your own thoughts and feelings and of " watching" yourself going about your business — as if you were looking at yourself from another persons vantage point. How does this happen ?

Evolution often takes advantage of pre-existing structures to evolve completely novel abilities. I suggest that once the ability to engage in cross modal abstraction emerged — e.g. between visual "vertical" on the retina and photoreceptive "vertical" signaled by muscles (for grasping trees) it set the stage for the emergence of mirror neurons in hominids. Mirror neurons are also abundant in the inferior parietal lobule — a structure that underwent an accelerated expansion in the great apes and, later, in humans. As the brain evolved further the lobule split into two gyri — the supramarginal gyrus that allowed you to "reflect" on your own anticipated actions and the angular gyrus that allowed you to "reflect" on your body (on the right) and perhaps on other more social and linguistic aspects of your self (left hemisphere).

I have argued elsewhere that mirror neurons are fundamentally performing a kind of abstraction across activity in visual maps and motor maps. This in turn may have paved the way for more conceptual types of abstraction; such as metaphor ("get a grip on yourself").

How does all this lead to self awareness? I suggest that self awareness is simply using mirror neurons for "looking at myself as if someone else is look at me" (the word "me" encompassing some of my brain processes, as well). The mirror neuron mechanism — the same algorithm — that originally evolved to help you adopt another's point of view was turned inward to look at your own self. This, in essence, is the basis of things like "introspection".... [T]he ability to turn inward to introspect or reflect may be a sort of metaphorical extension of the mirror neurons ability to read others minds.

It is often tacitly assumed that the uniquely human ability to construct a "theory of other minds" or "TOM" (seeing the world from the others point of view; "mind reading", figuring out what someone is up to, etc.) must come after an already pre-existing sense of self. I am arguing that the exact opposite is true; the TOM evolved first in response to social needs and then later, as an unexpected bonus, came the ability to introspect on your own thoughts and intentions.

I claim no great originality for these ideas; they are part of the current zeitgeist. Any novelty derives from the manner in which I shall marshall the evidence from physiology and from our own work in neurology. Note that I am not arguing that mirror neurons are sufficient for the emergence of self; only that they must have played a pivotal role. (Otherwise monkeys would have self awareness and they don't). They may have to reach a certain critical level of sophistication that allowed them to build on earlier functions (TOM) and become linked to certain other brain circuits, especially the Wernickes ("language comprehension") area and parts of the frontal lobes.

Does the mirror neuron theory of self make other predictions? Given our discovery that autistic children have deficient mirror neurons and correspondingly deficient TOM, we would predict that they would have a deficient sense of self (TMM) and difficulty with introspection. The same might be true for other neurological disorders; damage to the inferior parietal lobule/TPO junction (which are known to contain mirror neurons) and parts of the frontal lobes should also lead to a deficiency of certain aspects self awareness....

Some years ago we examined a patient with a syndrome called anosognosia who had a lesion in his right parietal lobe and vehemently denied the paralysis. Remarkably the patient also denied the paralysis of another patient sitting in an adjacent wheelchair! (who failed to move the arm on command from the physician.) Here again was, evidence that two seemingly contradictory aspects of self — its the individuation and intense privacy vs. its social reciprocity — may complement each other and arise from the same neural mechanism, mirror neurons. Like the two sides of a Mobius strip, they are really the same, even they appear — on local inspection — to be fundamentally different.

Have we solved the problem of self? Obviously not — we have barely scratched the surface. But hopefully we have paved the way for future models and empirical studies on the nature of self, a problem that philosophers have made essentially no headway in solving. (And not for want of effort — they have been at it for three thousand years). Hence our grounds for optimism about the future of brain research — especially for solving what is arguably Science's greatest riddle.

Comments

Edge: THE NEUROLOGY OF SELF-AWARENESS by V.S. Ramachandran: As noted earlier there is one aspect of self that seems stranger than all the others — the fact that it is aware of itself. I would like to suggest that groups of neurons called mirror neurons are critically involved in this ability.... [W]hen the monkey reached for a peanut a certain neuron in its pre motor cortex (in the frontal lobes) would fire. Another neuron would fire when the monkey pushed a button, a third neuron when he pulled a lever. The existence of such Command neurons that control voluntary movements has been known for decades. Amazingly, a subset of these neurons had an additional peculiar property. The neuron fired not only (say) when the monkey reached for a peanut but also when it watched another monkey reach for a peanut!

These were dubbed "mirror neurons" or "monkey-see-monkey-do" neurons. This was an extraordinary observation because it implies that the neuron (or more accurately, the network which it is part of) was not only generating a highly specific command ("reach for the nut") but was capable of adopting another monkey's point of view. It was doing a sort of internal virtual reality simulation of the other monkeys action in order to figure out what he was "up to". It was, in short, a "mind-reading" neuron.

Neurons in the anterior cingulate will respond to the patient being poked with a needle; they are often referred to as sensory pain neurons. Remarkably, researchers at the University of Toronto have found that some of them will fire equally strongly when the patient watches someone else is poked. I call these "empathy neurons" or "Dalai Lama neurons" for they are, dissolving the barrier between self and others. Notice that in saying this one isn't being metaphorical; the neuron in question simply doesn't know the difference between it and others.

Primates (including humans) are highly social creatures and knowing what someone is "up to" — creating an internal simulation of his/her mind — is crucial for survival, earning us the title "the Machiavellian primate". In an essay for Edge (2001) entitled "Mirror Neurons and the Great Leap Forward" I suggested that in addition to providing a neural substrate for figuring out another persons intentions (as noted by Rizzolati's group) the emergence and subsequent sophistication of mirror neurons in hominids may have played a crucial role in many quintessentially human abilities such as empathy, learning through imitation (rather than trial and error), and the rapid transmission of what we call "culture". And the "great leap forward" — the rapid Lamarckian transmission of "accidental" one-of-a kind inventions.

I turn now to the main concern of this essay — the nature of self. When you think of your own self, what comes into mind? You have sense of "introspecting" on your own thoughts and feelings and of " watching" yourself going about your business — as if you were looking at yourself from another persons vantage point. How does this happen ?

Evolution often takes advantage of pre-existing structures to evolve completely novel abilities. I suggest that once the ability to engage in cross modal abstraction emerged — e.g. between visual "vertical" on the retina and photoreceptive "vertical" signaled by muscles (for grasping trees) it set the stage for the emergence of mirror neurons in hominids. Mirror neurons are also abundant in the inferior parietal lobule — a structure that underwent an accelerated expansion in the great apes and, later, in humans. As the brain evolved further the lobule split into two gyri — the supramarginal gyrus that allowed you to "reflect" on your own anticipated actions and the angular gyrus that allowed you to "reflect" on your body (on the right) and perhaps on other more social and linguistic aspects of your self (left hemisphere).

I have argued elsewhere that mirror neurons are fundamentally performing a kind of abstraction across activity in visual maps and motor maps. This in turn may have paved the way for more conceptual types of abstraction; such as metaphor ("get a grip on yourself").

How does all this lead to self awareness? I suggest that self awareness is simply using mirror neurons for "looking at myself as if someone else is look at me" (the word "me" encompassing some of my brain processes, as well). The mirror neuron mechanism — the same algorithm — that originally evolved to help you adopt another's point of view was turned inward to look at your own self. This, in essence, is the basis of things like "introspection".... [T]he ability to turn inward to introspect or reflect may be a sort of metaphorical extension of the mirror neurons ability to read others minds.

It is often tacitly assumed that the uniquely human ability to construct a "theory of other minds" or "TOM" (seeing the world from the others point of view; "mind reading", figuring out what someone is up to, etc.) must come after an already pre-existing sense of self. I am arguing that the exact opposite is true; the TOM evolved first in response to social needs and then later, as an unexpected bonus, came the ability to introspect on your own thoughts and intentions.

I claim no great originality for these ideas; they are part of the current zeitgeist. Any novelty derives from the manner in which I shall marshall the evidence from physiology and from our own work in neurology. Note that I am not arguing that mirror neurons are sufficient for the emergence of self; only that they must have played a pivotal role. (Otherwise monkeys would have self awareness and they don't). They may have to reach a certain critical level of sophistication that allowed them to build on earlier functions (TOM) and become linked to certain other brain circuits, especially the Wernickes ("language comprehension") area and parts of the frontal lobes.

Does the mirror neuron theory of self make other predictions? Given our discovery that autistic children have deficient mirror neurons and correspondingly deficient TOM, we would predict that they would have a deficient sense of self (TMM) and difficulty with introspection. The same might be true for other neurological disorders; damage to the inferior parietal lobule/TPO junction (which are known to contain mirror neurons) and parts of the frontal lobes should also lead to a deficiency of certain aspects self awareness....

Some years ago we examined a patient with a syndrome called anosognosia who had a lesion in his right parietal lobe and vehemently denied the paralysis. Remarkably the patient also denied the paralysis of another patient sitting in an adjacent wheelchair! (who failed to move the arm on command from the physician.) Here again was, evidence that two seemingly contradictory aspects of self — its the individuation and intense privacy vs. its social reciprocity — may complement each other and arise from the same neural mechanism, mirror neurons. Like the two sides of a Mobius strip, they are really the same, even they appear — on local inspection — to be fundamentally different.

Have we solved the problem of self? Obviously not — we have barely scratched the surface. But hopefully we have paved the way for future models and empirical studies on the nature of self, a problem that philosophers have made essentially no headway in solving. (And not for want of effort — they have been at it for three thousand years). Hence our grounds for optimism about the future of brain research — especially for solving what is arguably Science's greatest riddle.

The Most-Recent Thirty

Probably Worth Reading...

We Are with Her!

Looking Forward to Four Years During Which Most if Not All of America's Potential for Human Progress Is Likely to Be Wasted

With each passing day Donald Trump looks more and more like Silvio Berlusconi: bunga-bunga governance, with a number of unlikely and unforeseen disasters and a major drag on the country--except in states where his policies are neutralized.

Nevertheless, remember: WE ARE WITH HER!

Definitely Worth Reading...

Blogging: What to Expect Here

The purpose of this weblog is to be the best possible portal into what I am thinking, what I am reading, what I think about what I am reading, and what other smart people think about what I am reading...

"Bring expertise, bring a willingness to learn, bring good humor, bring a desire to improve the world—and also bring a low tolerance for lies and bullshit..." — Brad DeLong

"I have never subscribed to the notion that someone can unilaterally impose an obligation of confidentiality onto me simply by sending me an unsolicited letter—or an email..." — Patrick Nielsen Hayden

"I can safely say that I have learned more than I ever would have imagined doing this.... I also have a much better sense of how the public views what we do. Every economist should have to sell ideas to the public once in awhile and listen to what they say. There's a lot to learn..." — Mark Thoma

"Tone, engagement, cooperation, taking an interest in what others are saying, how the other commenters are reacting, the overall health of the conversation, and whether you're being a bore..." — Teresa Nielsen Hayden

"With the arrival of Web logging... my invisible college is paradise squared, for an academic at least. Plus, web logging is an excellent procrastination tool.... Plus, every legitimate economist who has worked in government has left swearing to do everything possible to raise the level of debate and to communicate with a mass audience.... Web logging is a promising way to do that..." — Brad DeLong

"Blogs are an outlet for unexpurgated, unreviewed, and occasionally unprofessional musings.... At Chicago, I found that some of my colleagues overestimated the time and effort I put into my blog—which led them to overestimate lost opportunities for scholarship. Other colleagues maintained that they never read blogs—and yet, without fail, they come into my office once every two weeks to talk about a post of mine..." — Daniel Drezner